摘要
Mobile phones equipped with multiple wireless interfaces can increase their goodput performance by making use of concurrent transmissions over multiple paths, enabled by the Multipath TCP(MPTCP). However, utilizing MPTCP for data delivery may generally result in higher energy consumption, while the battery power of a mobile phone is limited. Thus, how to optimize the energy usage becomes very crucial and urgent. In this paper, we propose MPTCP.QE, a novel quality of experience(Qo E).driven energy.aware multipath content delivery approach for MPTCP.based mobile phones. The main idea of MPTCP.QE is described as follows: it first provides an application rate.aware energy.efficient subflow management strategy to tradeoff throughput performance and energy consumption for mobile phones; then uses an available bandwidth.aware congestion window fast recovery strategy to make a sender avoid unnecessary slow.start and utilize wireless resource quickly; and further introduces a novel receiver.driven energy.efficient SACK strategy to help a receiver possible to detect SACK loss timely and trigger loss recovery in a more energy.efficient way. The simulation results show that with the MPTCP.QE, the energy usage is enhanced while the performance level is maintained compared to existing MPTCP solutions.
Mobile phones equipped with multiple wireless interfaces can increase their goodput performance by making use of concurrent transmissions over multiple paths, enabled by the Multipath TCP (MPTCP). However, utilizing MPTCP for data delivery may generally result in higher energy consumption, while the battery power of a mobile phone is limited. Thus, how to optimize the energy usage becomes very crucial and urgent. In this paper, we propose MPTCP-QE, a nov- el quality of experience (QoE)-driven energy-aware multipath content delivery approach for MPTCP-based mobile phones. The main idea of MPTCP-QE is described as follows: it first provides an application rate-aware energy-efficient subflow management strategy to tradeoff throughput performance and energy consumption for mobile phones; then uses an available bandwidth-aware congestion window fast recovery strategy to make a sender avoid unnecessary stow-start and utilize wireless resource quickly; and further introduces a novel receiver-driven energy-efficient SACK strategy to help a receiver possible to detect SACK loss timely and trigger loss recovery in a more energy-efficient way. The simulation results show that with the MPTCP-QE, the energy usage is enhanced while the performance level is maintained compared to existing MPTCP solutions.
基金
supported by the National Natural Science Foundation of China (NSFC) under Grant No. 61562044, 61262014
the Natural Science Foundation of Jiangxi Province under Grant No. 20161BAB212046
the Project of Soft Science Research Plan of Jiangxi Province under Grant No. 20161BBA10010
the Science and Technology Research Project of Jiangxi Provincial Department of Education (GJJ150319)
the Higher School Teaching Reform Research Subject of Jiangxi Province(JXJG-15-2-35)
